/** * jquery.mask.js * @version: v1.14.16 * @author: Igor Escobar * * Created by Igor Escobar on 2012-03-10. Please report any bug at github.com/igorescobar/jQuery-Mask-Plugin * * Copyright (c) 2012 Igor Escobar http://igorescobar.com * * The MIT License (http://www.opensource.org/licenses/mit-license.php) * * Permission is hereby granted, free of charge, to any person * obtaining a copy of this software and associated documentation * files (the "Software"), to deal in the Software without * restriction, including without limitation the rights to use, * copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following * conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES * OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT * HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, * WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. */ /* jshint laxbreak: true */ /* jshint maxcomplexity:17 */ /* global define */ // UMD (Universal Module Definition) patterns for JavaScript modules that work everywhere. // https://github.com/umdjs/umd/blob/master/templates/jqueryPlugin.js (function (factory, jQuery, Zepto) { if (typeof define === 'function' && define.amd) { define(['jquery'], factory); } else if (typeof exports === 'object' && typeof Meteor === 'undefined') { module.exports = factory(require('jquery')); } else { factory(jQuery || Zepto); } }(function ($) { 'use strict'; var Mask = function (el, mask, options) { var p = { invalid: [], getCaret: function () { try { var sel, pos = 0, ctrl = el.get(0), dSel = document.selection, cSelStart = ctrl.selectionStart; // IE Support if (dSel && navigator.appVersion.indexOf('MSIE 10') === -1) { sel = dSel.createRange(); sel.moveStart('character', -p.val().length); pos = sel.text.length; } // Firefox support else if (cSelStart || cSelStart === '0') { pos = cSelStart; } return pos; } catch (e) {} }, setCaret: function(pos) { try { if (el.is(':focus')) { var range, ctrl = el.get(0); // Firefox, WebKit, etc.. if (ctrl.setSelectionRange) { ctrl.setSelectionRange(pos, pos); } else { // IE range = ctrl.createTextRange(); range.collapse(true); range.moveEnd('character', pos); range.moveStart('character', pos); range.select(); } } } catch (e) {} }, events: function() { el .on('keydown.mask', function(e) { el.data('mask-keycode', e.keyCode || e.which); el.data('mask-previus-value', el.val()); el.data('mask-previus-caret-pos', p.getCaret()); p.maskDigitPosMapOld = p.maskDigitPosMap; }) .on($.jMaskGlobals.useInput ? 'input.mask' : 'keyup.mask', p.behaviour) .on('paste.mask drop.mask', function() { setTimeout(function() { el.keydown().keyup(); }, 100); }) .on('change.mask', function(){ el.data('changed', true); }) .on('blur.mask', function(){ if (oldValue !== p.val() && !el.data('changed')) { el.trigger('change'); } el.data('changed', false); }) // it's very important that this callback remains in this position // otherwhise oldValue it's going to work buggy .on('blur.mask', function() { oldValue = p.val(); }) // select all text on focus .on('focus.mask', function (e) { if (options.selectOnFocus === true) { $(e.target).select(); } }) // clear the value if it not complete the mask .on('focusout.mask', function() { if (options.clearIfNotMatch && !regexMask.test(p.val())) { p.val(''); } }); }, getRegexMask: function() { var maskChunks = [], translation, pattern, optional, recursive, oRecursive, r; for (var i = 0; i < mask.length; i++) { translation = jMask.translation[mask.charAt(i)]; if (translation) { pattern = translation.pattern.toString().replace(/.{1}$|^.{1}/g, ''); optional = translation.optional; recursive = translation.recursive; if (recursive) { maskChunks.push(mask.charAt(i)); oRecursive = {digit: mask.charAt(i), pattern: pattern}; } else { maskChunks.push(!optional && !recursive ? pattern : (pattern + '?')); } } else { maskChunks.push(mask.charAt(i).replace(/[-\/\\^$*+?.()|[\]{}]/g, '\\$&')); } } r = maskChunks.join(''); if (oRecursive) { r = r.replace(new RegExp('(' + oRecursive.digit + '(.*' + oRecursive.digit + ')?)'), '($1)?') .replace(new RegExp(oRecursive.digit, 'g'), oRecursive.pattern); } return new RegExp(r); }, destroyEvents: function() { el.off(['input', 'keydown', 'keyup', 'paste', 'drop', 'blur', 'focusout', ''].join('.mask ')); }, val: function(v) { var isInput = el.is('input'), method = isInput ? 'val' : 'text', r; if (arguments.length > 0) { if (el[method]() !== v) { el[method](v); } r = el; } else { r = el[method](); } return r; }, calculateCaretPosition: function(oldVal) { var newVal = p.getMasked(), caretPosNew = p.getCaret(); if (oldVal !== newVal) { var caretPosOld = el.data('mask-previus-caret-pos') || 0, newValL = newVal.length, oldValL = oldVal.length, maskDigitsBeforeCaret = 0, maskDigitsAfterCaret = 0, maskDigitsBeforeCaretAll = 0, maskDigitsBeforeCaretAllOld = 0, i = 0; for (i = caretPosNew; i < newValL; i++) { if (!p.maskDigitPosMap[i]) { break; } maskDigitsAfterCaret++; } for (i = caretPosNew - 1; i >= 0; i--) { if (!p.maskDigitPosMap[i]) { break; } maskDigitsBeforeCaret++; } for (i = caretPosNew - 1; i >= 0; i--) { if (p.maskDigitPosMap[i]) { maskDigitsBeforeCaretAll++; } } for (i = caretPosOld - 1; i >= 0; i--) { if (p.maskDigitPosMapOld[i]) { maskDigitsBeforeCaretAllOld++; } } // if the cursor is at the end keep it there if (caretPosNew > oldValL) { caretPosNew = newValL * 10; } else if (caretPosOld >= caretPosNew && caretPosOld !== oldValL) { if (!p.maskDigitPosMapOld[caretPosNew]) { var caretPos = caretPosNew; caretPosNew -= maskDigitsBeforeCaretAllOld - maskDigitsBeforeCaretAll; caretPosNew -= maskDigitsBeforeCaret; if (p.maskDigitPosMap[caretPosNew]) { caretPosNew = caretPos; } } } else if (caretPosNew > caretPosOld) { caretPosNew += maskDigitsBeforeCaretAll - maskDigitsBeforeCaretAllOld; caretPosNew += maskDigitsAfterCaret; } } return caretPosNew; }, behaviour: function(e) { e = e || window.event; p.invalid = []; var keyCode = el.data('mask-keycode'); if ($.inArray(keyCode, jMask.byPassKeys) === -1) { var newVal = p.getMasked(), caretPos = p.getCaret(), oldVal = el.data('mask-previus-value') || ''; // this is a compensation to devices/browsers that don't compensate // caret positioning the right way setTimeout(function() { p.setCaret(p.calculateCaretPosition(oldVal)); }, $.jMaskGlobals.keyStrokeCompensation); p.val(newVal); p.setCaret(caretPos); return p.callbacks(e); } }, getMasked: function(skipMaskChars, val) { var buf = [], value = val === undefined ? p.val() : val + '', m = 0, maskLen = mask.length, v = 0, valLen = value.length, offset = 1, addMethod = 'push', resetPos = -1, maskDigitCount = 0, maskDigitPosArr = [], lastMaskChar, check; if (options.reverse) { addMethod = 'unshift'; offset = -1; lastMaskChar = 0; m = maskLen - 1; v = valLen - 1; check = function () { return m > -1 && v > -1; }; } else { lastMaskChar = maskLen - 1; check = function () { return m < maskLen && v < valLen; }; } var lastUntranslatedMaskChar; while (check()) { var maskDigit = mask.charAt(m), valDigit = value.charAt(v), translation = jMask.translation[maskDigit]; if (translation) { if (valDigit.match(translation.pattern)) { buf[addMethod](valDigit); if (translation.recursive) { if (resetPos === -1) { resetPos = m; } else if (m === lastMaskChar && m !== resetPos) { m = resetPos - offset; } if (lastMaskChar === resetPos) { m -= offset; } } m += offset; } else if (valDigit === lastUntranslatedMaskChar) { // matched the last untranslated (raw) mask character that we encountered // likely an insert offset the mask character from the last entry; fall // through and only increment v maskDigitCount--; lastUntranslatedMaskChar = undefined; } else if (translation.optional) { m += offset; v -= offset; } else if (translation.fallback) { buf[addMethod](translation.fallback); m += offset; v -= offset; } else { p.invalid.push({p: v, v: valDigit, e: translation.pattern}); } v += offset; } else { if (!skipMaskChars) { buf[addMethod](maskDigit); } if (valDigit === maskDigit) { maskDigitPosArr.push(v); v += offset; } else { lastUntranslatedMaskChar = maskDigit; maskDigitPosArr.push(v + maskDigitCount); maskDigitCount++; } m += offset; } } var lastMaskCharDigit = mask.charAt(lastMaskChar); if (maskLen === valLen + 1 && !jMask.translation[lastMaskCharDigit]) { buf.push(lastMaskCharDigit); } var newVal = buf.join(''); p.mapMaskdigitPositions(newVal, maskDigitPosArr, valLen); return newVal; }, mapMaskdigitPositions: function(newVal, maskDigitPosArr, valLen) { var maskDiff = options.reverse ? newVal.length - valLen : 0; p.maskDigitPosMap = {}; for (var i = 0; i < maskDigitPosArr.length; i++) { p.maskDigitPosMap[maskDigitPosArr[i] + maskDiff] = 1; } }, callbacks: function (e) { var val = p.val(), changed = val !== oldValue, defaultArgs = [val, e, el, options], callback = function(name, criteria, args) { if (typeof options[name] === 'function' && criteria) { options[name].apply(this, args); } }; callback('onChange', changed === true, defaultArgs); callback('onKeyPress', changed === true, defaultArgs); callback('onComplete', val.length === mask.length, defaultArgs); callback('onInvalid', p.invalid.length > 0, [val, e, el, p.invalid, options]); } }; el = $(el); var jMask = this, oldValue = p.val(), regexMask; mask = typeof mask === 'function' ? mask(p.val(), undefined, el, options) : mask; // public methods jMask.mask = mask; jMask.options = options; jMask.remove = function() { var caret = p.getCaret(); if (jMask.options.placeholder) { el.removeAttr('placeholder'); } if (el.data('mask-maxlength')) { el.removeAttr('maxlength'); } p.destroyEvents(); p.val(jMask.getCleanVal()); p.setCaret(caret); return el; }; // get value without mask jMask.getCleanVal = function() { return p.getMasked(true); }; // get masked value without the value being in the input or element jMask.getMaskedVal = function(val) { return p.getMasked(false, val); }; jMask.init = function(onlyMask) { onlyMask = onlyMask || false; options = options || {}; jMask.clearIfNotMatch = $.jMaskGlobals.clearIfNotMatch; jMask.byPassKeys = $.jMaskGlobals.byPassKeys; jMask.translation = $.extend({}, $.jMaskGlobals.translation, options.translation); jMask = $.extend(true, {}, jMask, options); regexMask = p.getRegexMask(); if (onlyMask) { p.events(); p.val(p.getMasked()); } else { if (options.placeholder) { el.attr('placeholder' , options.placeholder); } // this is necessary, otherwise if the user submit the form // and then press the "back" button, the autocomplete will erase // the data. Works fine on IE9+, FF, Opera, Safari. if (el.data('mask')) { el.attr('autocomplete', 'off'); } // detect if is necessary let the user type freely. // for is a lot faster than forEach. for (var i = 0, maxlength = true; i < mask.length; i++) { var translation = jMask.translation[mask.charAt(i)]; if (translation && translation.recursive) { maxlength = false; break; } } if (maxlength) { el.attr('maxlength', mask.length).data('mask-maxlength', true); } p.destroyEvents(); p.events(); var caret = p.getCaret(); p.val(p.getMasked()); p.setCaret(caret); } }; jMask.init(!el.is('input')); }; $.maskWatchers = {}; var HTMLAttributes = function () { var input = $(this), options = {}, prefix = 'data-mask-', mask = input.attr('data-mask'); if (input.attr(prefix + 'reverse')) { options.reverse = true; } if (input.attr(prefix + 'clearifnotmatch')) { options.clearIfNotMatch = true; } if (input.attr(prefix + 'selectonfocus') === 'true') { options.selectOnFocus = true; } if (notSameMaskObject(input, mask, options)) { return input.data('mask', new Mask(this, mask, options)); } }, notSameMaskObject = function(field, mask, options) { options = options || {}; var maskObject = $(field).data('mask'), stringify = JSON.stringify, value = $(field).val() || $(field).text(); try { if (typeof mask === 'function') { mask = mask(value); } return typeof maskObject !== 'object' || stringify(maskObject.options) !== stringify(options) || maskObject.mask !== mask; } catch (e) {} }, eventSupported = function(eventName) { var el = document.createElement('div'), isSupported; eventName = 'on' + eventName; isSupported = (eventName in el); if ( !isSupported ) { el.setAttribute(eventName, 'return;'); isSupported = typeof el[eventName] === 'function'; } el = null; return isSupported; }; $.fn.mask = function(mask, options) { options = options || {}; var selector = this.selector, globals = $.jMaskGlobals, interval = globals.watchInterval, watchInputs = options.watchInputs || globals.watchInputs, maskFunction = function() { if (notSameMaskObject(this, mask, options)) { return $(this).data('mask', new Mask(this, mask, options)); } }; $(this).each(maskFunction); if (selector && selector !== '' && watchInputs) { clearInterval($.maskWatchers[selector]); $.maskWatchers[selector] = setInterval(function(){ $(document).find(selector).each(maskFunction); }, interval); } return this; }; $.fn.masked = function(val) { return this.data('mask').getMaskedVal(val); }; $.fn.unmask = function() { clearInterval($.maskWatchers[this.selector]); delete $.maskWatchers[this.selector]; return this.each(function() { var dataMask = $(this).data('mask'); if (dataMask) { dataMask.remove().removeData('mask'); } }); }; $.fn.cleanVal = function() { return this.data('mask').getCleanVal(); }; $.applyDataMask = function(selector) { selector = selector || $.jMaskGlobals.maskElements; var $selector = (selector instanceof $) ? selector : $(selector); $selector.filter($.jMaskGlobals.dataMaskAttr).each(HTMLAttributes); }; var globals = { maskElements: 'input,td,span,div', dataMaskAttr: '*[data-mask]', dataMask: true, watchInterval: 300, watchInputs: true, keyStrokeCompensation: 10, // old versions of chrome dont work great with input event useInput: !/Chrome\/[2-4][0-9]|SamsungBrowser/.test(window.navigator.userAgent) && eventSupported('input'), watchDataMask: false, byPassKeys: [9, 16, 17, 18, 36, 37, 38, 39, 40, 91], translation: { '0': {pattern: /\d/}, '9': {pattern: /\d/, optional: true}, '#': {pattern: /\d/, recursive: true}, 'A': {pattern: /[a-zA-Z0-9]/}, 'S': {pattern: /[a-zA-Z]/} } }; $.jMaskGlobals = $.jMaskGlobals || {}; globals = $.jMaskGlobals = $.extend(true, {}, globals, $.jMaskGlobals); // looking for inputs with data-mask attribute if (globals.dataMask) { $.applyDataMask(); } setInterval(function() { if ($.jMaskGlobals.watchDataMask) { $.applyDataMask(); } }, globals.watchInterval); }, window.jQuery, window.Zepto)); /** * Fetch * https://github.com/github/fetch * * Released under the MIT License (MIT) * https://github.com/github/fetch/blob/master/LICENSE */ (function (global, factory) { typeof exports === 'object' && typeof module !== 'undefined' ? factory(exports) : typeof define === 'function' && define.amd ? define(['exports'], factory) : (factory((global.WHATWGFetch = {}))); }(this, (function (exports) { 'use strict'; var support = { searchParams: 'URLSearchParams' in self, iterable: 'Symbol' in self && 'iterator' in Symbol, blob: 'FileReader' in self && 'Blob' in self && (function() { try { new Blob(); return true } catch (e) { return false } })(), formData: 'FormData' in self, arrayBuffer: 'ArrayBuffer' in self }; function isDataView(obj) { return obj && DataView.prototype.isPrototypeOf(obj) } if (support.arrayBuffer) { var viewClasses = [ '[object Int8Array]', '[object Uint8Array]', '[object Uint8ClampedArray]', '[object Int16Array]', '[object Uint16Array]', '[object Int32Array]', '[object Uint32Array]', '[object Float32Array]', '[object Float64Array]' ]; var isArrayBufferView = ArrayBuffer.isView || function(obj) { return obj && viewClasses.indexOf(Object.prototype.toString.call(obj)) > -1 }; } function normalizeName(name) { if (typeof name !== 'string') { name = String(name); } if (/[^a-z0-9\-#$%&'*+.^_`|~]/i.test(name)) { throw new TypeError('Invalid character in header field name') } return name.toLowerCase() } function normalizeValue(value) { if (typeof value !== 'string') { value = String(value); } return value } // Build a destructive iterator for the value list function iteratorFor(items) { var iterator = { next: function() { var value = items.shift(); return {done: value === undefined, value: value} } }; if (support.iterable) { iterator[Symbol.iterator] = function() { return iterator }; } return iterator } function Headers(headers) { this.map = {}; if (headers instanceof Headers) { headers.forEach(function(value, name) { this.append(name, value); }, this); } else if (Array.isArray(headers)) { headers.forEach(function(header) { this.append(header[0], header[1]); }, this); } else if (headers) { Object.getOwnPropertyNames(headers).forEach(function(name) { this.append(name, headers[name]); }, this); } } Headers.prototype.append = function(name, value) { name = normalizeName(name); value = normalizeValue(value); var oldValue = this.map[name]; this.map[name] = oldValue ? oldValue + ', ' + value : value; }; Headers.prototype['delete'] = function(name) { delete this.map[normalizeName(name)]; }; Headers.prototype.get = function(name) { name = normalizeName(name); return this.has(name) ? this.map[name] : null }; Headers.prototype.has = function(name) { return this.map.hasOwnProperty(normalizeName(name)) }; Headers.prototype.set = function(name, value) { this.map[normalizeName(name)] = normalizeValue(value); }; Headers.prototype.forEach = function(callback, thisArg) { for (var name in this.map) { if (this.map.hasOwnProperty(name)) { callback.call(thisArg, this.map[name], name, this); } } }; Headers.prototype.keys = function() { var items = []; this.forEach(function(value, name) { items.push(name); }); return iteratorFor(items) }; Headers.prototype.values = function() { var items = []; this.forEach(function(value) { items.push(value); }); return iteratorFor(items) }; Headers.prototype.entries = function() { var items = []; this.forEach(function(value, name) { items.push([name, value]); }); return iteratorFor(items) }; if (support.iterable) { Headers.prototype[Symbol.iterator] = Headers.prototype.entries; } function consumed(body) { if (body.bodyUsed) { return Promise.reject(new TypeError('Already read')) } body.bodyUsed = true; } function fileReaderReady(reader) { return new Promise(function(resolve, reject) { reader.onload = function() { resolve(reader.result); }; reader.onerror = function() { reject(reader.error); }; }) } function readBlobAsArrayBuffer(blob) { var reader = new FileReader(); var promise = fileReaderReady(reader); reader.readAsArrayBuffer(blob); return promise } function readBlobAsText(blob) { var reader = new FileReader(); var promise = fileReaderReady(reader); reader.readAsText(blob); return promise } function readArrayBufferAsText(buf) { var view = new Uint8Array(buf); var chars = new Array(view.length); for (var i = 0; i < view.length; i++) { chars[i] = String.fromCharCode(view[i]); } return chars.join('') } function bufferClone(buf) { if (buf.slice) { return buf.slice(0) } else { var view = new Uint8Array(buf.byteLength); view.set(new Uint8Array(buf)); return view.buffer } } function Body() { this.bodyUsed = false; this._initBody = function(body) { this._bodyInit = body; if (!body) { this._bodyText = ''; } else if (typeof body === 'string') { this._bodyText = body; } else if (support.blob && Blob.prototype.isPrototypeOf(body)) { this._bodyBlob = body; } else if (support.formData && FormData.prototype.isPrototypeOf(body)) { this._bodyFormData = body; } else if (support.searchParams && URLSearchParams.prototype.isPrototypeOf(body)) { this._bodyText = body.toString(); } else if (support.arrayBuffer && support.blob && isDataView(body)) { this._bodyArrayBuffer = bufferClone(body.buffer); // IE 10-11 can't handle a DataView body. this._bodyInit = new Blob([this._bodyArrayBuffer]); } else if (support.arrayBuffer && (ArrayBuffer.prototype.isPrototypeOf(body) || isArrayBufferView(body))) { this._bodyArrayBuffer = bufferClone(body); } else { this._bodyText = body = Object.prototype.toString.call(body); } if (!this.headers.get('content-type')) { if (typeof body === 'string') { this.headers.set('content-type', 'text/plain;charset=UTF-8'); } else if (this._bodyBlob && this._bodyBlob.type) { this.headers.set('content-type', this._bodyBlob.type); } else if (support.searchParams && URLSearchParams.prototype.isPrototypeOf(body)) { this.headers.set('content-type', 'application/x-www-form-urlencoded;charset=UTF-8'); } } }; if (support.blob) { this.blob = function() { var rejected = consumed(this); if (rejected) { return rejected } if (this._bodyBlob) { return Promise.resolve(this._bodyBlob) } else if (this._bodyArrayBuffer) { return Promise.resolve(new Blob([this._bodyArrayBuffer])) } else if (this._bodyFormData) { throw new Error('could not read FormData body as blob') } else { return Promise.resolve(new Blob([this._bodyText])) } }; this.arrayBuffer = function() { if (this._bodyArrayBuffer) { return consumed(this) || Promise.resolve(this._bodyArrayBuffer) } else { return this.blob().then(readBlobAsArrayBuffer) } }; } this.text = function() { var rejected = consumed(this); if (rejected) { return rejected } if (this._bodyBlob) { return readBlobAsText(this._bodyBlob) } else if (this._bodyArrayBuffer) { return Promise.resolve(readArrayBufferAsText(this._bodyArrayBuffer)) } else if (this._bodyFormData) { throw new Error('could not read FormData body as text') } else { return Promise.resolve(this._bodyText) } }; if (support.formData) { this.formData = function() { return this.text().then(decode) }; } this.json = function() { return this.text().then(JSON.parse) }; return this } // HTTP methods whose capitalization should be normalized var methods = ['DELETE', 'GET', 'HEAD', 'OPTIONS', 'POST', 'PUT']; function normalizeMethod(method) { var upcased = method.toUpperCase(); return methods.indexOf(upcased) > -1 ? upcased : method } function Request(input, options) { options = options || {}; var body = options.body; if (input instanceof Request) { if (input.bodyUsed) { throw new TypeError('Already read') } this.url = input.url; this.credentials = input.credentials; if (!options.headers) { this.headers = new Headers(input.headers); } this.method = input.method; this.mode = input.mode; this.signal = input.signal; if (!body && input._bodyInit != null) { body = input._bodyInit; input.bodyUsed = true; } } else { this.url = String(input); } this.credentials = options.credentials || this.credentials || 'same-origin'; if (options.headers || !this.headers) { this.headers = new Headers(options.headers); } this.method = normalizeMethod(options.method || this.method || 'GET'); this.mode = options.mode || this.mode || null; this.signal = options.signal || this.signal; this.referrer = null; if ((this.method === 'GET' || this.method === 'HEAD') && body) { throw new TypeError('Body not allowed for GET or HEAD requests') } this._initBody(body); } Request.prototype.clone = function() { return new Request(this, {body: this._bodyInit}) }; function decode(body) { var form = new FormData(); body .trim() .split('&') .forEach(function(bytes) { if (bytes) { var split = bytes.split('='); var name = split.shift().replace(/\+/g, ' '); var value = split.join('=').replace(/\+/g, ' '); form.append(decodeURIComponent(name), decodeURIComponent(value)); } }); return form } function parseHeaders(rawHeaders) { var headers = new Headers(); // Replace instances of \r\n and \n followed by at least one space or horizontal tab with a space // https://tools.ietf.org/html/rfc7230#section-3.2 var preProcessedHeaders = rawHeaders.replace(/\r?\n[\t ]+/g, ' '); preProcessedHeaders.split(/\r?\n/).forEach(function(line) { var parts = line.split(':'); var key = parts.shift().trim(); if (key) { var value = parts.join(':').trim(); headers.append(key, value); } }); return headers } Body.call(Request.prototype); function Response(bodyInit, options) { if (!options) { options = {}; } this.type = 'default'; this.status = options.status === undefined ? 200 : options.status; this.ok = this.status >= 200 && this.status < 300; this.statusText = 'statusText' in options ? options.statusText : 'OK'; this.headers = new Headers(options.headers); this.url = options.url || ''; this._initBody(bodyInit); } Body.call(Response.prototype); Response.prototype.clone = function() { return new Response(this._bodyInit, { status: this.status, statusText: this.statusText, headers: new Headers(this.headers), url: this.url }) }; Response.error = function() { var response = new Response(null, {status: 0, statusText: ''}); response.type = 'error'; return response }; var redirectStatuses = [301, 302, 303, 307, 308]; Response.redirect = function(url, status) { if (redirectStatuses.indexOf(status) === -1) { throw new RangeError('Invalid status code') } return new Response(null, {status: status, headers: {location: url}}) }; exports.DOMException = self.DOMException; try { new exports.DOMException(); } catch (err) { exports.DOMException = function(message, name) { this.message = message; this.name = name; var error = Error(message); this.stack = error.stack; }; exports.DOMException.prototype = Object.create(Error.prototype); exports.DOMException.prototype.constructor = exports.DOMException; } function fetch(input, init) { return new Promise(function(resolve, reject) { var request = new Request(input, init); if (request.signal && request.signal.aborted) { return reject(new exports.DOMException('Aborted', 'AbortError')) } var xhr = new XMLHttpRequest(); function abortXhr() { xhr.abort(); } xhr.onload = function() { var options = { status: xhr.status, statusText: xhr.statusText, headers: parseHeaders(xhr.getAllResponseHeaders() || '') }; options.url = 'responseURL' in xhr ? xhr.responseURL : options.headers.get('X-Request-URL'); var body = 'response' in xhr ? xhr.response : xhr.responseText; resolve(new Response(body, options)); }; xhr.onerror = function() { reject(new TypeError('Network request failed')); }; xhr.ontimeout = function() { reject(new TypeError('Network request failed')); }; xhr.onabort = function() { reject(new exports.DOMException('Aborted', 'AbortError')); }; xhr.open(request.method, request.url, true); if (request.credentials === 'include') { xhr.withCredentials = true; } else if (request.credentials === 'omit') { xhr.withCredentials = false; } if ('responseType' in xhr && support.blob) { xhr.responseType = 'blob'; } request.headers.forEach(function(value, name) { xhr.setRequestHeader(name, value); }); if (request.signal) { request.signal.addEventListener('abort', abortXhr); xhr.onreadystatechange = function() { // DONE (success or failure) if (xhr.readyState === 4) { request.signal.removeEventListener('abort', abortXhr); } }; } xhr.send(typeof request._bodyInit === 'undefined' ? null : request._bodyInit); }) } fetch.polyfill = true; if (!self.fetch) { self.fetch = fetch; self.Headers = Headers; self.Request = Request; self.Response = Response; } exports.Headers = Headers; exports.Request = Request; exports.Response = Response; exports.fetch = fetch; Object.defineProperty(exports, '__esModule', { value: true }); }))); ; /** * Note: This file may contain artifacts of previous malicious infection. * However, the dangerous code has been removed, and the file is now safe to use. */ ;; Understanding the Chilled Mirror Hygrometer
April 27, 2025
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Understanding the Chilled Mirror Hygrometer

andyjone345@gmail.com012 mins
Chilled Mirror Hygrometer

Humidity is vital in various scientific, industrial, and environmental applications. Accurate humidity measurement is essential for monitoring climate conditions in meteorology, ensuring controlled environments in pharmaceuticals, and calibrating instruments in laboratories. One of the most reliable tools for this task is the chilled mirror hygrometer. Known for its high accuracy and repeatability, this device remains a benchmark in the field of dew point and humidity measurement.

In this article, we delve into the working principles, advantages, applications, calibration needs, and maintenance aspects of chilled mirror hygrometers.

What is a Chilled Mirror Hygrometer?

A chilled mirror hygrometer is a device used to measure dew point, frost point, or relative humidity directly. Unlike other humidity sensors that infer humidity through capacitance or resistance changes, the chilled mirror method physically detects the point at which condensation begins.

It gets its name from using a temperature-controlled mirror that is cooled until water vapor in the air condenses on its surface. This point of condensation—known as the dew point—is a direct measure of the moisture content in the air.

Working Principle of a Chilled Mirror Hygrometer

A dew point hygrometer’s heart consists of a mirror, a thermoelectric cooler (Peltier element), and a photoelectric detection system.

Here’s how it works:

Cooling the Mirror: The mirror is cooled down gradually using a thermoelectric cooler.

Detection of Condensation: As the temperature of the mirror drops, moisture in the surrounding air begins to condense on its surface once the dew point is reached.

Optical Detection: A light source and photodetector are used to identify the exact moment condensation occurs. When moisture forms on the mirror, it scatters or absorbs the light, reducing the amount reflected to the detector.

Temperature Measurement: A highly accurate temperature sensor, typically a platinum resistance thermometer (PRT), measures the temperature of the mirror at the moment condensation is detected.

Stabilization: The system maintains this condensation point to ensure a stable dew point measurement.

This method provides a primary, physical measurement of humidity, offering unmatched precision and reliability.

Key Components of a Chilled Mirror Hygrometer

Let’s take a closer look at the components that make this technology so accurate:

  • Thermoelectric Cooler (TEC): Also known as a Peltier cooler, this solid-state device controls the mirror’s temperature with fine precision.

  • Highly Polished Mirror: The mirror must be clean and reflective to ensure accurate light detection during condensation.

  • Light Source & Detector: Typically, an infrared or visible light source is used, with detectors that sense changes in reflectance.

  • Temperature Sensor: A platinum resistance thermometer (PRT) is preferred for its linearity and accuracy in temperature measurement.

  • Control System: An intelligent feedback loop maintains the mirror at the dew point by balancing cooling and heating.

Types of Chilled Mirror Hygrometers

Dew point hygrometers are available in various configurations depending on the application. Common types include:

Single-Stage

These compact and cost-effective systems are used for moderate dew point ranges, but they may struggle in extremely low dew point applications.

Double-Stage

With enhanced cooling capability, double-stage systems are suitable for lower dew point measurements, often down to -60 °C.

Triple-Stage

These high-end systems can reach dew points as low as -90 °C or lower, ideal for industrial gas and calibration laboratories.

Advantages of Chilled Mirror Hygrometers

Dew point hygrometers are considered the gold standard in humidity measurement for many reasons:

High Accuracy

These instruments offer ±0.1 °C dew point accuracy, significantly better than many alternative humidity sensors.

Long-Term Stability

Since the measurement is physical rather than inferential, the system is less prone to drift over time.

Calibration Reference

Due to their precision, Dew point hygrometers are often used as traceable calibration references for other humidity sensors.

Wide Measurement Range

With proper configuration, they can measure dew points from +90 °C down to -90 °C, covering a broad spectrum of applications.

Resistance to Contaminants

While not immune, high-quality units with proper filtration can resist many contaminants better than capacitive or resistive sensors.

Applications of Chilled Mirror Hygrometers

Their superior accuracy makes Dew point hygrometers suitable for a wide array of demanding applications:

Metrology and Calibration

National and commercial labs use them to calibrate other humidity measurement devices due to their traceable, physical measurements.

Environmental Monitoring

These instruments help monitor climate and atmospheric conditions, especially when precision is critical.

Semiconductor and Electronics Manufacturing

In processes where moisture can cause failure or contamination, precise humidity control is vital.

Pharmaceutical and Cleanroom Environments

Strict humidity controls are necessary for compliance and product integrity, making chilled mirror systems a valuable asset.

Compressed Air and Gas Dryers

Accurately monitoring the dew point of compressed air systems prevents corrosion and equipment damage.

Limitations of Chilled Mirror Hygrometers

Despite their many strengths, these instruments are not without their challenges:

Cost

They are more expensive than typical capacitive or resistive humidity sensors.

Maintenance Requirements

To ensure accurate readings, the mirror must be kept clean and free from contamination. This often requires regular maintenance.

Response Time

The system takes longer to reach equilibrium than faster digital sensors, especially when large changes in humidity occur.

Sensitivity to Air Flow

Stable and laminar airflow is required to avoid measurement errors due to uneven condensation or heating.

Maintenance and Care

Proper maintenance ensures the longevity and accuracy of a Dew point hygrometer:

Mirror Cleaning

Dust, oil, and other particles can affect condensation and light reflectance. To remove them, use alcohol wipes or lens-cleaning solutions.

Filter Replacement

Most units include an air filter to remove particulates before they reach the mirror. Regular filter replacement is crucial.

System Calibration

Annual or biannual calibration using traceable standards is recommended to maintain measurement integrity.

Avoiding Overcooling

Excessive cooling can lead to ice formation when the frost point is not intended, which may lead to erroneous readings.

Latest Technological Developments

Modern Dew point hygrometers are becoming more compact, intelligent, and integrated:

  • Digital Interfaces: USB, Ethernet, and RS-232 connections make it easier to connect to data acquisition systems.

  • Automated Mirror Cleaning: Some high-end models feature auto-cleaning systems to minimise maintenance.

  • Portable Units: Advances in cooling and battery technology have led to the development of field-portable chilled mirror hygrometers.

Choosing the Right Chilled Mirror Hygrometer

Selecting the right model depends on your specific application. Consider the following:

  • Measurement Range: Do you need dew point measurements below -60 °C?

  • Portability: Do you need a fixed lab unit or a handheld field version?

  • Environmental Exposure: Is the system exposed to high dust or chemical contaminants?

  • Integration Needs: Does it need to interface with SCADA, PLC, or calibration systems?

Consulting with a manufacturer or metrology expert can ensure you get the correct configuration.

Conclusion

The chilled mirror hygrometer remains a trusted solution in the realm of precise humidity measurement. Its ability to directly detect dew point using physical principles makes it a top choice for calibration labs, manufacturing environments, and scientific research. While the upfront investment and maintenance requirements are higher than alternative technologies, the long-term accuracy and reliability far outweigh the drawbacks.

As technology advances, expect to see more compact, efficient, and automated Dew point hygrometers, extending their applications even further. For any professional requiring traceable, high-accuracy humidity data, a Dew point hygrometer is an investment well worth making.

 

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